"""
.. _ex-trap-music:

=================================
Compute Trap-Music on evoked data
=================================

Compute a Truncated Recursively Applied and Projected MUltiple Signal Classification
(TRAP-MUSIC) :footcite:`Makela2018` on evoked data.
"""

# Author: Théodore Papadopoulo <Theodore.Papadopoulo@inria.fr>
#
# License: BSD-3-Clause
# Copyright the MNE-Python contributors.

# %%

import mne
from mne.beamformer import trap_music
from mne.datasets import sample
from mne.viz import plot_dipole_amplitudes, plot_dipole_locations

print(__doc__)

data_path = sample.data_path()
subjects_dir = data_path / "subjects"
meg_path = data_path / "MEG" / "sample"
fwd_fname = meg_path / "sample_audvis-meg-eeg-oct-6-fwd.fif"
evoked_fname = meg_path / "sample_audvis-ave.fif"
cov_fname = meg_path / "sample_audvis-cov.fif"

# Read the evoked response and crop it
condition = "Right Auditory"
evoked = mne.read_evokeds(evoked_fname, condition=condition, baseline=(None, 0))
# select N100
evoked.crop(tmin=0.05, tmax=0.15)

evoked.pick(picks="meg", exclude="bads")

# Read the forward solution
forward = mne.read_forward_solution(fwd_fname)

# Read noise covariance matrix
noise_cov = mne.read_cov(cov_fname)

dipoles, residual = trap_music(
    evoked, forward, noise_cov, n_dipoles=2, return_residual=True, verbose=True
)
trans = forward["mri_head_t"]
plot_dipole_locations(dipoles, trans, "sample", subjects_dir=subjects_dir)
plot_dipole_amplitudes(dipoles)

# Plot the evoked data and the residual.
evoked.plot(ylim=dict(grad=[-300, 300], mag=[-800, 800], eeg=[-6, 8]), time_unit="s")
residual.plot(ylim=dict(grad=[-300, 300], mag=[-800, 800], eeg=[-6, 8]), time_unit="s")

# %%
# References
# ----------
# .. footbibliography::
